Lower-extremity amputation as a marker for renal and cardiovascular events and mortality in patients with long standing type 1 diabetes

HAL Id: inserm-01252613

https://www.hal.inserm.fr/inserm-01252613

Submitted on 7 Jan 2016

HAL is a multi-disciplinary open access archive for the deposit and dissemination of sci- entific research documents, whether they are pub- lished or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers.

L’archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d’enseignement et de recherche français ou étrangers, des laboratoires publics ou privés.

Lower-extremity amputation as a marker for renal and cardiovascular events and mortality in patients with long

standing type 1 diabetes

Kamel Mohammedi, Louis Potier, Narimène Belhatem, Nadia Matallah, Samy Hadjadj, Ronan Roussel, Michel Marre, Gilberto Velho

To cite this version:

Kamel Mohammedi, Louis Potier, Narimène Belhatem, Nadia Matallah, Samy Hadjadj, et al.. Lower- extremity amputation as a marker for renal and cardiovascular events and mortality in patients with long standing type 1 diabetes. Cardiovascular Diabetology, BioMed Central, 2016, 15 (1), pp.5.

�10.1186/s12933-015-0322-0�. �inserm-01252613�

ORIGINAL INVESTIGATION

Lower-extremity amputation as a

marker for renal and cardiovascular events and mortality in patients with long standing type 1 diabetes

Kamel Mohammedi ^1,2* , Louis Potier ^1,2,3 , Narimène Belhatem ^1,2 , Nadia Matallah ^1,2 , Samy Hadjadj ^4,5,6,7 , Ronan Roussel ^1,2,3 , Michel Marre ^1,2,3 and Gilberto Velho ¹

Abstract

Background: We evaluated the risks of renal and cardiovascular complications, and mortality associated with lower extremity amputation (LEA) in patients with type 1 diabetes.

Methods: We studied two cohorts of people with long standing type 1 diabetes: GENEDIAB (n = 456) and GENESIS (n = 611). Subsets of the cohorts (n = 260, n = 544) were followed for 9 and 5 years, respectively. Outcomes were the incidence of end stage renal disease (ESRD), myocardial infarction, stroke and mortality during follow-up. Analyses were performed in pooled cohorts.

Results: The prevalence of LEA at baseline was 9.3 % (n = 99). A positive history of LEA was associated with the baseline prevalence of established (OR 4.50, 95 % CI 2.33–8.91, p < 0.0001) and advanced diabetic nephropathy (OR 5.50, 95 % CI 2.89–10.78, p < 0.0001), ESRD (OR 2.86, 95 % CI 1.43–5.50, p = 0.004), myocardial infarction (OR 3.25, 95 % CI 1.68–6.15, p = 0.0006) and stroke (OR 3.88, 95 % CI 1.67–8.72, p = 0.002, adjusted for sex, age, and cohort membership). A positive history of LEA at baseline was associated with the incidence during follow-up of ESRD (HR 2.69, 95 % CI 1.17–6.20, p = 0.02), and myocardial infarction (HR 3.53, 95 % CI 1.79–6.97, p = 0.0001). History of LEA was also associated with increased risk for all-cause (HR 3.55, 95 % CI 2.05–6.16, p < 0.0001), cardiovascular (HR 3.30, 95 % CI 1.36–8.02, p = 0.008), infectious disease (HR 5.18, 95 % CI 1.13–23.84, p = 0.03) and other-cause mortality (HR 2.81, 95 % CI 1.09–7.26, p = 0.03). History of LEA at baseline was associated with a 40 % reduction in the duration of survival in the subset of patients who died during follow- up. Population attributable risk of the history of LEA at baseline for total mortality during follow-up was 0.31.

Conclusions: Patients with LEA have a higher risk of ESRD, myocardial infarction and cardiovascular and non-car- diovascular mortality. Our results highlight the importance of LEA as a key-predictor for major vascular events and premature death in type 1 diabetic patients.

Keywords: Type 1 diabetes, Amputation, Diabetic nephropathy, End stage renal disease, Myocardial infarction, Stroke, Mortality

© 2016 Mohammedi et al. This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.

org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Background

Lower extremity amputation (LEA) is a severe and fre- quent complication in patients with diabetes [1, 2].

Despite a decline of its incidence in Europe and USA in the past decades, LEA remains higher in patients with diabetes as compared to those without diabetes [3–8]. Moreover, LEA-related mortality is higher in diabetic patients than in the general population [9–11].

It is a major public health problem worldwide, with a significant social and economic burden. LEA requires lengthy hospitalizations with frequent and repeated

Open Access

*Correspondence: [email protected]

2

Department of Diabetology, Endocrinology and Nutrition, Assistance

Publique Hôpitaux de Paris, Bichat Hospital, DHU FIRE, Paris, France

Full list of author information is available at the end of the article

Page 2 of 9 Mohammedi et al. Cardiovasc Diabetol (2016) 15:5

revascularization procedures, supplemented by special- ized outpatient care [12, 13]. It might result in crippling physical and psychological sequelae, with a negative impact on the quality of life, leading to social and profes- sional disabilities [14].

Type 1 diabetes is associated with increased risk of pre- mature death [15, 16], and this increased mortality risk is related mainly to kidney and cardiovascular compli- cations [15, 17–19]. LEA is also associated with higher cardiovascular mortality in people with diabetes [20, 21]. However, data on LEA and risk of cardiovascular and kidney complications, and cause-specific mortality in patients with type 1 diabetes are scarce. In the present investigation we evaluated LEA-related risk of kidney and cardiovascular complications, and cardiovascular and non-cardiovascular mortality in two cohorts of patients with type 1 diabetes.

Methods Participants

We studied two multicentre binational (Belgium and France) cohorts of people with long standing type 1 dia- betes designed to study the vascular complications of diabetes. GENEDIAB (Génétique de la Néphropathie Diabétique) was a prospective cohort conducted, from 1994 to 2006, in 494 participants with type 1 diabe- tes selected on the basis of diagnosis of type 1 diabetes before the age of 35 years and past or present diagnosis of severe diabetic retinopathy [22]. The Genesis France- Belgium (GENESIS) cohort was a family-based study conducted, from 1999 to 2007, in 578 first-degree rela- tives and 662 probands with type 1 diabetes, selected on the basis of a diagnosis of type 1 diabetes before the age of 35 years, with initial ketosis and requirement for per- manent insulin treatment within 1 year of diagnosis and past or present diagnosis of diabetic retinopathy [23].

In the present investigation, we analysed at baseline 456 GENEDIAB participants and 611 GENESIS probands for whom LEA data was available. Clinical characteristics of GENEDIAB and GENESIS participants at baseline are shown in the Additional file 1: Table S1.

Follow‑up study

In a prospective observational study, subsets of GEN- EDIAB (n  = 260) and GENESIS (n  = 544) participants were followed until an end point was reached or until February 2007. The subsets were composed of partici- pants who attended outpatient clinics at least once dur- ing the follow-up period. Median duration of follow-up (and interquartile range) was 10.2 (2.7) and 5.1 (1.5) years for GENEDIAB and GENESIS, respectively. Clini- cal characteristics at baseline of GENESIS participants for whom follow-up data were available were similar to

those of participants without follow-up data (Additional file  1: Table S1). GENEDIAB participants for whom fol- low-up data were available as compared to those without follow-up data, were older, had higher eGFR and lower prevalence of advanced diabetic nephropathy at baseline.

Participants of the two cohorts gave written informed consent, and study protocols were approved by the eth- ics committee of Angers University Hospital (Angers, France).

Definition of clinical parameters and outcomes

An ad hoc event committee reviewed the case record of each patient to validate the diagnosis of renal, retinal, and cardiovascular complications, peripheral sensory neu- ropathy, peripheral artery disease and LEA at baseline [22] and later, the incidence of outcomes during follow- up. LEA was adjudicated as amputation of a lower limb (above or below the knee, foot, toes or transmetatarsal) resulting from non-traumatic causes. Glomerular fil- tration rate (eGFR) was estimated by the Modification of Diet in Renal Disease (MDRD) formula [24]. Stages of diabetic nephropathy were defined as follows: no nephropathy, defined as urinary albumin concentra- tion (UAC) <30 mg/24 h or <20 µg/min or <20 mg/l and plasma creatinine  <150  µmol/l in at least 2 of 3 con- secutive assessments and in the absence of antihyper- tensive treatment; incipient nephropathy, defined as persistent microalbuminuria (UAC  =  30–300  mg/24  h or 20–200  µg/min or 20–200  mg/l) and plasma creati- nine  <150  µmol/l; established nephropathy, defined as past or present macroalbuminuria (UAC > 300 mg/24 h or  >  200  µg/min or  >  200  mg/l) and plasma creati- nine  <150  µmol/l; and advanced nephropathy, defined as past or present macroalbuminuria and plasma creati- nine  >150  µmol/l or history of end stage renal disease (ESRD), defined as haemodialysis requirement or kidney transplantation. Ocular data was obtained by direct fun- duscopy and/or fluorescein angiography. Diabetic retin- opathy was staged according to Kohner’s classification as non-proliferative, pre-proliferative or proliferative retin- opathy [25]. Myocardial infarction was diagnosed as the occurrence of at least 2 out of 3 of the following criteria:

constrictive chest pain lasting 20 min or longer, increased

serum creatinine phosphokinase and/or troponine lev-

els, or typical electrocardiographic changes. Stroke was

diagnosed as the occurrence of a focal neurologic defi-

cit lasting at least 24 h, associated with evidence of brain

infarction or haemorrhage by computed tomography or

magnetic resonance imaging. Incidences of ESRD, myo-

cardial infarction or stroke were defined as new cases

of these outcomes during follow-up. The cause of death

was established from hospital records. Missing data

were completed by a phone interview with the patient’s

general practitioner and/or by consulting the death cer- tificate national registry. All-cause mortality was defined as death of any cause occurring during follow-up. Cardi- ovascular death was defined as death following myocar- dial infarction, congestive heart failure, arrhythmias and stroke. Infectious disease mortality was defined as death complicating infectious disease.

Statistical analysis

Results are expressed as mean ± SD except when stated otherwise. Differences between groups were assessed by analysis of variance (ANOVA), analysis of covariance (ANCOVA), and Pearson’s Chi squared test. If the nor- mality of the distribution was rejected by the Shapiro–

Wilk W test, data were log-transformed for the analyses, or Wilcoxon/Kruskal–Wallis test was used. Associa- tions of a history of LEA with the prevalence of diabetic complications at baseline were examined with logistic regression analyses. Kaplan–Meier curves were used to plot the cumulative incidences of outcomes over time by the baseline history of LEA. Cox proportional hazards survival regression analyses were used to examine the effect of explanatory variables on time-related survival (or outcome-free) rates in prospective analyses. Hazard ratios (HR) or odds ratios (OR), respectively, with their 95 % confidence intervals (CI) were computed for a posi- tive history of LEA at baseline. Competing risk regres- sion analysis (Fine and Gray model) was performed to estimate subhazard ratios of ESRD, myocardial infarc- tion or stroke assuming death as a competing risk [26].

Adjustments for clinical and biological parameters were performed by including these parameters as covariates in the regression models. Cross-sectional stepwise mul- tivariable regression analysis of covariates associated with the prevalences of the clinical outcomes at the end of follow-up were performed as sensitivity analyses. The incidence of ESRD, myocardial infarction, stroke or death during follow-up could not be ascertained in 62, 16, 30 and 7 participants, respectively. Those participants were not excluded from the study, but only from the analy- ses of the specific outcome where data were missing. To increase statistical power, all analyses were performed in GENEDIAB and GENESIS pooled cohorts, with appro- priate adjustments for covariates to take into account cohort differences. p  ≤  0.05 was considered as signifi- cant. Statistics were performed with the JMP (SAS Insti- tute Inc., Cary, NC, USA) and Stata (StataCorp, College Station, TX, USA) softwares.

Results

Clinical characteristics of participants at baseline

The prevalence of LEA at baseline was 9.3 % (n = 99) in GENEDIAB/GENESIS pooled cohorts. Characteristics

of participants by a history of LEA at baseline are shown in Table 1. Individuals with a positive history of LEA as compared to other participants were more likely to be men, were older at baseline and had a longer duration of diabetes. They had higher blood pressure levels, were more likely to take antihypertensive medication and to have a history of tobacco smoking. Diabetic retinopathy, peripheral sensory neuropathy and peripheral artery dis- ease were more frequent in individuals with LEA.

LEA and kidney and cardiovascular complications at baseline

Participants with a positive history of LEA at baseline had higher UAC and lower eGFR as compared to par- ticipants without LEA history. Diabetic nephropathy at baseline was more frequent and more severe in partici- pants with a positive history of LEA (Table  1). Regres- sion analyses confirmed the associations of a positive history of LEA at baseline with the prevalence of estab- lished and advanced diabetic nephropathy at baseline:

OR 4.50, 95 % CI 2.33–8.91, p < 0.0001 and OR 5.50, 95 % CI 2.89–10.78, p < 0.0001, respectively, in a model with minimal covariate adjustment (model 1: sex, age, and cohort membership). Associations remained significant in a multi-adjusted model taking into account differences between groups at baseline (model 2: sex, age, cohort membership, duration of diabetes, HbA1c, use of anti- hypertensive and lipids lowering drugs, and history of tobacco smoking): OR 4.49, 95 % CI 2.11–9.79, p < 0.0001 and OR 6.22, 95 % CI 2.92–13.73, p < 0.0001, for estab- lished and advanced diabetic nephropathy respectively.

The prevalence of ESRD at baseline was 7.3 % (n = 78). It was higher in participants with a positive history of LEA than in other participants (15.2 vs 6.5  %, Pearson’s Chi squared test p  =  0.002). Regression analyses confirmed the association of a positive history of LEA with the base- line prevalence of ESRD (Additional file 1: Table S2).

The prevalences of previous myocardial infarction and stroke at baseline were 5.7 % (n = 61) and 3.3 % (n = 35), respectively. Prevalences were significantly higher in participants with a positive history of LEA than in other participants: 19.2 vs. 4.4  %, respectively, for myocar- dial infarction (Pearson’s Chi squared test p  <  0.0001), and 11.1 vs. 2.5 %, respectively, for stroke (Pearson’s Chi squared test p = 0.0001). Regression analyses, with mini- mal and multi-adjusted models, confirmed the associa- tion of LEA with the prevalence of previous myocardial infarction and stroke at baseline (Additional file 1: Table S2).

LEA and clinical outcomes during follow‑up

Cumulative incidences of ESRD, myocardial infarction

and stroke during follow-up were 7.4 % (n  = 55), 6.2 %

Page 4 of 9 Mohammedi et al. Cardiovasc Diabetol (2016) 15:5

(n  = 49) and 3.4 % (n  = 26), respectively. The incidence rate of these outcomes was 1.2, 1.0, and 0.5 per 100 per- son-years, respectively. Characteristics of participants at

baseline by the incidence of each of the outcomes dur- ing follow-up are shown in the Additional file 1: Table S3.

Characteristics by ESRD and myocardial infarction status during follow-up were partially published previously [27, 28]. Briefly, incident cases of ESRD, myocardial infarction or stroke during follow-up, compared to participants not presenting these outcomes, were older and had a longer duration of diabetes at baseline (except for ESRD cases), had higher blood pressure, lower eGFR (except for stroke cases), higher UAC (except for myocardial infarction cases), and were more likely to be taking antihypertensive drugs and to present peripheral sensory neuropathy and peripheral artery disease. Diabetic nephropathy and dia- betic retinopathy were more frequent and more severe in incident cases of each outcome.

The incidences of ESRD, myocardial infarction and stroke during follow-up were higher in participants with a positive history of LEA at baseline than in other par- ticipants (Table  2). Cox proportional hazards survival regression analyses confirmed the association of a posi- tive history of LEA at baseline with the incidence dur- ing follow-up of ESRD and myocardial infarction both in minimal and multi-adjusted models (Table 2). No sig- nificant association was observed with the incidence of stroke. Kaplan–Meier (cumulative incidence) curves for ESRD and myocardial infarction during follow-up by the history of LEA at baseline are shown in Fig. 1. The asso- ciation with the incidence of ESRD remained significant when we excluded participants with advanced nephropa- thy at baseline, and when we also excluded participants with established nephropathy at baseline (p = 0.003 and p = 0.03, respectively, for the multi-adjusted model; data not shown). Similarly, the association with the incidence of myocardial infarction during follow-up remained sig- nificant when we excluded from the analysis participants with a history of previous myocardial infarction at base- line, or when we included the history of previous myo- cardial infarction at baseline as a covariate in the model (p  =  0.001 and p  =  0.01, respectively, for the multi- adjusted model; data not shown).

The associations of a positive history of LEA at base- line with the incidence of ESRD and myocardial infarc- tion evaluated with the Cox model might be biased by the association of LEA with all-cause mortality (see below) if many patients died before achieving the renal or the coronary endpoint. Therefore, we performed compet- ing risk regression analyses to estimate subhazard ratios (SHR) for a positive history of LEA as a risk for ESRD or myocardial infarction assuming all-cause mortality as a competing risk. SHR and HR from the Cox model were similar, indicating that death was not a competing risk in the association of LEA with ESRD or myocardial infarc- tion (Table 2, model 3).

Table 1 Characteristics of  participants by  the history of lower extremity amputation at baseline

Results expressed as mean  ±  SD, except urinary albumin concentration (UAC) and triglycerides expressed as mean (interquartile range). Statistics of quantitative parameters are ANOVA performed with log-transformed data or Wilcoxon test (UAC and triglycerides). Antihypertensive drugs: all antihypertensive medication classes included. ACE-I angiotensin converting enzyme inhibitor, ARB angiotensin receptor blocker. Diabetic nephropathy stages: absence, incipient, established, and advanced nephropathy. Diabetic retinopathy stages: absent, non-proliferative, pre-proliferative, proliferative

a

Data available only in the GENEDIAB cohort: n  =  438 for total cholesterol and n  =  129 for triglycerides

b

Current or past history of tobacco smoking p < 0.05 was significant

History of LEA at baseline p

No Yes

N (%) 968 (90.7) 99 (9.3)

Male sex (%) 51.9 70.7 0.0003

Age (years) 42.6 ± 11.6 51.6 ± 11.2 <0.0001

Age at diabetes onset

(years) 15.5 ± 9.1 18.3 ± 9.0 0.007

Duration of diabetes

(years) 27.0 ± 9.3 33.3 ± 9.0 <0.0001

Body mass index (kg/

m

) 24.1 ± 3.5 23.9 ± 3.8 0.40

Systolic BP (mmHg) 134 ± 19 143 ± 20 <0.0001

Diastolic BP (mmHg) 77 ± 11 80 ± 11 0.003

HbA1c (%) and

(mmol/mol) 8.5 ± 1.5 (70 ± 16) 8.8 ± 2.1 (72 ± 23) 0.31 Plasma creatinine

(µmol/l) 113 ± 112 166 ± 163 <0.0001

eGFR (ml/

min/1.73 m

) 81 ± 44 60 ± 37 <0.0001

UAC (mg/l) 22 (238) 95 (499) 0.01

Total cholesterol

(mmol/l) 5.70 ± 1.45 5.67 ± 1.45 0.68

Triglycerides

(mmol/l) 1.13 (0.91) 1.29 (0.5) 0.31

Tobacco smoking

(%) 42.3 55.1 0.01

Antihypertensive

drugs (%) 51.1 73.7 <0.0001

ACE-I or ARB drugs

(%) 41.3 55.6 0.006

Lipid lowering drugs

(%) 8.4 11.1 0.35

Diabetic nephropa-

thy stages (%) 46/21/18/15 18/17/30/35 <0.0001 Diabetic retinopathy

stages (%) 0/27/18/55 0/4/15/81 <0.0001

Peripheral sensory

neuropathy (%) 46.4 89.7 <0.0001

Peripheral artery

disease (%) 5.8 93.8 <0.0001

LEA at baseline and mortality during follow‑up

Death occurred in 72 participants during the follow-up.

The cumulative incidence of all-cause mortality was 9.0 % (incidence rate 1.4 per 100 person-years). It was higher in participants with a positive history of LEA at base- line than in other participants (Table  3). Clinical char- acteristics of participants at baseline by the incidence of all-cause mortality during follow-up were partially published previously [27] and are shown in the Addi- tional file 1: Table S3. Briefly, participants who died dur- ing follow-up, as compared to those who survived, were older at baseline, more frequently of the male sex, had a longer duration of diabetes, higher HbA1c, blood pres- sure, and UAC levels. They had lower eGFR and were more likely to have a previous history of tobacco smok- ing, hypertension and myocardial infarction, and to pre- sent peripheral sensory neuropathy and peripheral artery disease. Diabetic nephropathy and diabetic retinopathy were more frequent and more severe in participants who died during follow-up. Cox proportional hazards survival regression analyses showed a significant association of a positive history of LEA at baseline with all cause mortal- ity during follow-up both in minimal and multi-adjusted models (Table  3). Kaplan–Meier (cumulative incidence) curve during follow-up by the history of LEA at baseline are shown in Fig.  1. A positive history of LEA at base- line was associated with a 40 % reduction in the duration of survival in the subset of participants who died dur- ing follow-up (2.9 ± 0.7 vs 4.8 ± 0.4 years, mean ± SD, p  = 0.02, adjusted for sex, age, duration of diabetes and cohort membership). Population attributable risk of the

history of LEA at baseline for total mortality during fol- low-up was 0.31.

Causes of death during follow-up included cardiovas- cular complications (38.9 %), infectious diseases (13.9 %), cancer (9.7  %), acute metabolic complications (8.3  %), kidney complications (2.8  %) and other or undeter- mined aetiologies (26.4  %). We assessed associations of LEA with cause-specific mortality grouped as cardio- vascular mortality, infectious disease mortality, and all other causes of death. For the 3 causes of mortality, the incidence during follow-up was higher in participants with a positive history of LEA at baseline than in other participants (Table  3). Cox proportional hazards sur- vival regression analyses confirmed the association of a positive history of LEA at baseline with the incidence of cardiovascular mortality and other causes of mortal- ity during follow-up in a model with minimal covari- ate adjustment (Table  3). No significant association was observed for infectious disease mortality. However, in a multi-adjusted model, associations of LEA were statisti- cally significant with the incidence of the 3 cause-specific mortalities (Table  3). No significant association of LEA at baseline with cancer mortality was observed (data not shown).

Sensitivity analyses

For sensitivity analyses, we performed cross-sectional stepwise multivariable regression analyses with the prev- alences of diabetic nephropathy, myocardial infarction, stroke and all-cause mortality as dependent variables.

To increase power, we used for each participant the most Table 2 Clinical outcomes during follow-up by history of LEA at baseline

Data expressed as number of cases and (%) by line. Hazards ratio (HR) for a positive LEA history at baseline as a risk for ESRD, myocardial infarction and stroke during follow-up, computed by Cox proportional hazards survival regressive analysis. Model 1: adjusted for cohort membership, sex and age at baseline. Model 2: adjusted for cohort membership, sex, age, duration of diabetes, HbA1c, systolic and diastolic blood pressure and diabetic retinopathy at baseline (risk for ESRD analysis), plus UAC and eGFR (risk for myocardial infarction and stroke analyses). Diabetic retinopathy was coded as an ordinal polytomic covariate: non-Proliferative (2), pre-Proliferative (3), proliferative (4). Subhazard ratio (SHR) for a positive LEA history at baseline as a risk for ESRD, myocardial infarction and stroke during follow-up, assuming death as a competing risk. SHR computed by competing risk regression analysis, adjusted for cohort membership, sex and age at baseline

p < 0.05 is significant

Clinical outcomes during follow‑up

ESRD Myocardial infarction Stroke

No Yes No Yes No Yes

LEA at baseline

No 644 (93.1 %) 48 (6.9 %) 697 (95.5 %) 33 (4.5 %) 698 (97.1 %) 21 (2.9 %)

Yes 44 (86.3 %) 7 (13.7 %) 43 (72.9 %) 16 (27.1 %) 51 (91.1) 5 (8.9 %)

HR (95 % CI) model 1 2.69 (1.17–6.20) 3.53 (1.79–6.97) 1.76 (0.60–5.14)

P 0.02 0.0001 0.29

HR (95 % CI) model 2 2.49 (1.02–6.06) 3.21 (1.50– 6.85) 1.28 (0.37–4.43)

P 0.04 0.003 0.69

SHR (95 % CI) model 3 2.41 (1.04–5.87) 3.16 (1.53–6.52) 1.49 (0.46–4.84)

P 0.04 0.002 0.50

Page 6 of 9 Mohammedi et al. Cardiovasc Diabetol (2016) 15:5

recent set of data available (follow-up, or baseline data if follow-up data was not available). Diabetic nephropathy was coded as an ordinal polytomic covariate: absence (1), incipient (2), established (3) and advanced nephropathy (4), and ESRD (5). For diabetic nephropathy analysis, sex, age, BMI, systolic and diastolic blood pressure, duration of diabetes, diabetic retinopathy stage, HbA1c, history of LEA, history of tobacco smoking, use of lipid lower- ing, antihypertensive and angiotensin converting enzyme inhibitor (ACE-I) or angiotensin 2 receptor blocker (ARB) drugs, and cohort membership were entered in the model as independent covariates. For myocardial infarction and stroke analyses, eGFR and UAC were also included as independent covariates. For all-cause mortality analysis,

diabetic nephropathy, myocardial infarction and stroke were also included as independent covariates. Thus, use of antihypertensive and lipid lowering drugs, history of LEA, proliferative diabetic retinopathy, and systolic blood pressure remained positively associated, and age and BMI inversely associated with diabetic nephropa- thy (Additional file  1: Table S4), and explained  ~12  % of the variation of the trait (cumulated R ² ). History of LEA, age and use of lipid lowering and antihypertensive drugs remained positively associated, and eGFR inversely associated with the prevalence of myocardial infarction (Additional file 1: Table S5), and explained ~18 % of the variation of the trait. Systolic blood pressure, duration of diabetes, UAC and history of LEA remained positively associated with the prevalence of stroke (Additional file 1: Table S6), and explained ~14 % of the variation of the trait. History of LEA, diabetic nephropathy, myocar- dial infarction, HbA1c, tobacco smoking, cohort mem- bership (GENEDIAB), BMI and age remained positively associated with all-cause mortality (Additional file  1:

Table S7), and explained  ~36  % of the variation of the trait. History of LEA in these stepwise regression analy- ses explained 1.4, 9.0, 1.1 and 14.1 % of the variation of the four traits, respectively, and provided the highest sin- gle increase in cumulated R ² in myocardial infarction and all-cause mortality regression models.

Discussion

In the present investigation in people with type 1 dia- betes, a positive history of LEA was associated with the prevalence of established and advanced diabetic nephropathy, ESRD, myocardial infarction and stroke at baseline. LEA at baseline was also associated with increased risk during follow-up of ESRD, myocardial infarction, all-cause mortality, and specifically, with mortality due to cardiovascular and infectious diseases.

When considering the participants who died during fol- low-up, a positive history of LEA at baseline was asso- ciated with a 40 % reduction in the duration of survival.

Population attributable risk of a positive history of LEA at baseline regarding all-cause mortality during follow- up, that is, the reduction in mortality that would be observed in our cohorts in the absence of LEA was 31 %.

Risk factors of lower‑extremity amputation

As in any epidemiological study, these associations may be confounded by other factors. For instance, blood glu- cose control and duration of diabetes are known risk factors for LEA [20, 29, 30], but also for cardiovascular and renal complications of diabetes. However, the asso- ciations we have observed with the incidence of ESRD and myocardial infarction were independent of relevant covariates such as sex, age, duration of diabetes, blood Fig. 1 Incidence of outcomes by the history of LEA at baseline.

Kaplan–Meier curves for the cumulative incidence of end stage renal

disease (ESRD), myocardial infarction, and all-cause mortality during

follow-up by the presence (dashed lines) or the absence (solid lines) of

a history of LEA at baseline

pressure, HbA1c, UAC, eGFR, antihypertensive and lipid lowering treatments, and the current and past history of tobacco smoking, suggesting that LEA was an independ- ent predictor for the clinical outcomes during follow-up.

Moreover, despite the association of LEA with mortality, death was not a competing risk in the association of LEA with the incidence of ESRD and myocardial infarction.

Lower‑extremity amputation and risks of kidney and cardiovascular complications and mortality

Increased mortality risk associated with LEA has been reported previously in people with diabetes [10, 21], but to the best of our knowledge, this is the first study that investigates the risk associated with a history of LEA on the prevalence and the incidence of cardiovascular and kidney diseases, and specific causes of mortality in pro- spective cohorts of type 1 diabetes. Increased risk of mor- tality in type 1 diabetic individuals with a baseline history of LEA as compared to those without LEA was observed in the WHO Multinational Study of Vascular Disease in Diabetes [20]. The Danish Amputation Register, includ- ing 1406 type 1 diabetic patients, reported higher rate of mortality in patients with LEA as compared to those without, particularly during the first year following the amputation [31]. A history of LEA was also reported as an independent predictor for 5-year mortality in 1444 patients with type 1 diabetes from the Early Treatment Diabetic Retinopathy Study [32]. On the other hand, the presence of chronic kidney disease (GFR  <  60  ml/

min) and ESRD were associated with increased rates of mortality (46 and 290  %, respectively) in patients with diabetes who undergone LEA [33]. LEA was reported in 1.5–2.5 % of participants in Swedish, German and Amer- ican surveys of people with type 1 diabetes [6, 34–36].

The higher prevalence of LEA in our cohorts at baseline (9.3  %) probably reflects the inclusion criteria, which

included the presence of retinopathy for GENESIS and severe (pre-proliferative or proliferative) retinopathy for GENEDIAB. Participants from our cohorts were older, had a longer duration of diabetes and were more severely ill than participants from the other surveys.

Strengths and limitations

LEA is the consequence of acute and chronic podiatric complications, including diabetic neuropathy, peripheral artery disease, skin microangiopathy with impairment of skin blood flow, coagulation disorders and infection complications [37–40]. The main limitation of our study was that data on specific causes of LEA and on the level of amputation (above or below the knee, foot, or toes), obtained retrospectively from hospital records, were fragmentary and could not be used in the investigation.

Another limitation was the relatively small number of some of the outcomes, potentially reducing the statisti- cal power to observe associations such as in the case of the incidence of stroke or some specific causes of death, including kidney disease-related mortality. The main strength of our study is the cross-sectional analysis of 1000 patients with long standing type 1 diabetes from two independent cohorts, with a follow-up of 5–9 years of more than 800 participants, with detailed renal, cardi- ovascular and survival outcomes including cause-specific mortality data. It is noteworthy that in cross-sectional analyses of total prevalence of diabetic nephropathy, myocardial infarction, stroke and all-cause mortality, LEA remained significantly associated with the all traits, including stroke.

Conclusions

LEA reflects widespread micro- and macrovascular dam- age in people with type 1 diabetes. Patients with LEA have a higher risk of ESRD, myocardial infarction and Table 3 Mortality during follow-up by history of LEA at baseline

Data expressed as number of cases and (%) by line. Hazards ratio (HR) for a positive LEA history at baseline as a risk for all-cause mortality, cardiovascular, infectious disease, and other causes of mortality during follow-up, computed by Cox proportional hazards survival regressive analysis. Model 1: adjusted for cohort membership, sex and age at baseline. Model 2: adjusted for cohort membership, sex, age, duration of diabetes, HbA1c, UAC, eGFR, use of antihypertensive and lipids lowering drugs, and history of tobacco smoking

p < 0.05 is significant

All‑cause mortality Cardiovascular mortality Infectious disease mortality Other causes of mortality

No Yes No Yes No Yes No Yes

LEA at baseline

No 691 (93.6 %) 47 (6.4 %) 691 (97.5 %) 18 (2.5 %) 691 (99.0 %) 7 (1.0 %) 691 (96.9 %) 22 (3.1 %)

Yes 36 (59.0 %) 25 (41.0 %) 36 (78.3 %) 10 (21.7 %) 36 (92.3 %) 3 (7.7 %) 36 (75.0 %) 12 (25.0 %)

HR (95 % CI) model 1 3.55 (2.05–6.16) 4.04 (1.69–9.62) 3.28 (0.73 –14.68) 3.25 (1.44–7.30)

P <0.0001 0.002 0.12 0.004

HR (95 % CI) model 2 2.73 (1.49–5.01) 3.30 (1.36–8.02) 5.18 (1.13–23.84) 2.81 (1.09–7.26)

P 0.001 0.008 0.03 0.03

Page 8 of 9 Mohammedi et al. Cardiovasc Diabetol (2016) 15:5

premature death from cardiovascular and non-cardio- vascular causes. Our results confirm the burden of LEA in patients with type 1 diabetes beyond podiatric issues, and highlight the importance of LEA as a key-predictor of severe outcomes.

Abbreviations

ACE-I: angiotensin converting enzyme inhibitor; ARB: angiotensin receptor blocker; eGFR: estimated glomerular filtration rate; ESRD: end-stage renal dis- ease; GENEDIAB: “Génétique de la Néphropathie Diabétique” Study; GENESIS:

genesis France-Belgium cohort; LEA: lower extremity amputation; MDRD:

modification of diet in renal disease formula; SHR: subhazard ratio; UAC:

urinary albumin concentration.

Authors’ contributions

KM and GV designed the study, researched data and wrote the manuscript.

LP, NB, NM, SH, RR and MM contributed to discussion and reviewed/edited manuscript. All authors read and approved the final manuscript.

Author details

1

INSERM, UMRS 1138, Centre de Recherche des Cordeliers, Paris, France.

2

Department of Diabetology, Endocrinology and Nutrition, Assistance Pub- lique Hôpitaux de Paris, Bichat Hospital, DHU FIRE, Paris, France.

Univ Paris Diderot, Sorbonne Paris Cité, UFR de Médecine, Paris, France.

Department of Endocrinology and Diabetology, Centre Hospitalier Universitaire de Poitiers, Poitiers, France.

INSERM, Research Unit 1082, Poitiers, France.

INSERM, CIC 1402, Poitiers, France.

UFR de Médecine et Pharmacie, Université de Poitiers, Poitiers, France.

Acknowledgements

This work was supported by grants from Association Diabète Risque Vasculaire (ADRV).

Competing interests

The authors declare that they have no competing interests.

Received: 17 September 2015 Accepted: 23 December 2015

References

1. Fosse S, Hartemann-Heurtier A, Jacqueminet S, Van Ha G, Grimaldi A, Fagot-Campagna A. Incidence and characteristics of lower limb amputa- tions in people with diabetes. Diabet Med. 2009;26(4):391–6.

2. Moxey PW, Hofman D, Hinchliffe RJ, Jones K, Thompson MM, Holt PJ.

Epidemiological study of lower limb amputation in England between 2003 and 2008. Br J Surg. 2010;97(9):1348–53.

3. Canavan RJ, Unwin NC, Kelly WF, Connolly VM. Diabetes- and nondia- betes-related lower extremity amputation incidence before and after the introduction of better organized diabetes foot care: continuous longitudinal monitoring using a standard method. Diabetes Care.

2008;31(3):459–63.

4. van Houtum WH, Rauwerda JA, Ruwaard D, Schaper NC, Bakker K. Reduc- tion in diabetes-related lower-extremity amputations in The Netherlands:

1991–2000. Diabetes Care. 2004;27(5):1042–6.

5. Resnick HE, Carter EA, Sosenko JM, Henly SJ, Fabsitz RR, Ness FK, et al.

Incidence of lower-extremity amputation in American Indians: the Strong Heart Study. Diabetes Care. 2004;27(8):1885–91.

6. Jonasson JM, Ye W, Sparen P, Apelqvist J, Nyren O, Brismar K. Risks of nontraumatic lower-extremity amputations in patients with type 1

Additional file

Additional file 1. Supplementary Tables.

diabetes: a population-based cohort study in Sweden. Diabetes Care.

2008;31(8):1536–40.

7. Ikonen TS, Sund R, Venermo M, Winell K. Fewer major amputations among individuals with diabetes in Finland in 1997–2007: a population- based study. Diabetes Care. 2010;33(12):2598–603.

8. Lopez-de-Andres A, Martinez-Huedo MA, Carrasco-Garrido P, Hernandez- Barrera V, Gil-de-Miguel A, Jimenez-Garcia R. Trends in lower-extremity amputations in people with and without diabetes in Spain, 2001–2008.

Diabetes Care. 2011;34(7):1570–6.

9. Aulivola B, Hile CN, Hamdan AD, Sheahan MG, Veraldi JR, Skillman JJ, et al.

Major lower extremity amputation: outcome of a modern series. Arch Surg. 2004;139(4):395–9 (discussion 399).

10. Schofield CJ, Libby G, Brennan GM, MacAlpine RR, Morris AD, Leese GP.

Mortality and hospitalization in patients after amputation: a com- parison between patients with and without diabetes. Diabetes Care.

2006;29(10):2252–6.

11. Hambleton IR, Jonnalagadda R, Davis CR, Fraser HS, Chaturvedi N, Hennis AJ. All-cause mortality after diabetes-related amputation in Barbados: a prospective case-control study. Diabetes Care. 2009;32(2):306–7.

12. Mahoney EM, Wang K, Keo HH, Duval S, Smolderen KG, Cohen DJ, et al.

Vascular hospitalization rates and costs in patients with peripheral artery dis- ease in the United States. Circ Cardiovasc Qual Outcomes. 2010;3(6):642–51.

13. Malyar N, Furstenberg T, Wellmann J, Meyborg M, Luders F, Gebauer K, et al. Recent trends in morbidity and in-hospital outcomes of in-patients with peripheral arterial disease: a nationwide population-based analysis.

Eur Heart J. 2013;34(34):2706–14.

14. Hirai FE, Tielsch JM, Klein BE, Klein R. Ten-year change in self-rated quality of life in a type 1 diabetes population: Wisconsin Epidemiologic Study of Diabetic Retinopathy. Qual Life Res. 2013;22(6):1245–53.

15. Soedamah-Muthu SS, Fuller JH, Mulnier HE, Raleigh VS, Lawrenson RA, Colhoun HM. All-cause mortality rates in patients with type 1 diabetes mellitus compared with a non-diabetic population from the UK general practice research database, 1992–1999. Diabetologia. 2006;49(4):660–6.

16. Lind M, Svensson AM, Kosiborod M, Gudbjornsdottir S, Pivodic A, Wedel H, et al. Glycemic control and excess mortality in type 1 diabetes. N Engl J Med. 2014;371(21):1972–82.

17. Orchard TJ, Secrest AM, Miller RG, Costacou T. In the absence of renal disease, 20 year mortality risk in type 1 diabetes is comparable to that of the general population: a report from the Pittsburgh Epidemiology of Diabetes Complications Study. Diabetologia. 2010;53(11):2312–9.

18. Soedamah-Muthu SS, Fuller JH, Mulnier HE, Raleigh VS, Lawrenson RA, Colhoun HM. High risk of cardiovascular disease in patients with type 1 diabetes in the UK: a cohort study using the general practice research database. Diabetes Care. 2006;29(4):798–804.

19. Seshasai SR, Kaptoge S, Thompson A, Di Angelantonio E, Gao P, Sarwar N, et al. Diabetes mellitus, fasting glucose, and risk of cause-specific death.

N Engl J Med. 2011;364(9):829–41.

20. Chaturvedi N, Stevens LK, Fuller JH, Lee ET, Lu M. Risk factors, ethnic differences and mortality associated with lower-extremity gangrene and amputation in diabetes. The WHO Multinational Study of Vascular Disease in Diabetes. Diabetologia. 2001;44(Suppl 2):S65–71.

21. Resnick HE, Carter EA, Lindsay R, Henly SJ, Ness FK, Welty TK, et al. Relation of lower-extremity amputation to all-cause and cardiovascular disease mortality in American Indians: the Strong Heart Study. Diabetes Care.

2004;27(6):1286–93.

22. Marre M, Jeunemaitre X, Gallois Y, Rodier M, Chatellier G, Sert C, et al. Con- tribution of genetic polymorphism in the renin-angiotensin system to the development of renal complications in insulin-dependent diabetes:

Genetique de la Nephropathie Diabetique (GENEDIAB) study group. J Clin Invest. 1997;99(7):1585–95.

23. Hadjadj S, Pean F, Gallois Y, Passa P, Aubert R, Weekers L, et al. Different patterns of insulin resistance in relatives of type 1 diabetic patients with retinopathy or nephropathy: the Genesis France-Belgium Study. Diabetes Care. 2004;27(11):2661–8.

24. Levey AS, Bosch JP, Lewis JB, Greene T, Rogers N, Roth D. A more accurate method to estimate glomerular filtration rate from serum creatinine: a new prediction equation. Modification of Diet in Renal Disease Study Group. Ann Intern Med. 1999;130(6):461–70.

25. Kohner EM. The lesions and natural history of diabetic retinopathy. In:

Pickup J, Williams G, editors. Textbook of diabetes. Oxford: Blackwell

Scientific; 1991. p. 575–88.

• We accept pre-submission inquiries

• Our selector tool helps you to find the most relevant journal

• We provide round the clock customer support

• Convenient online submission

• Thorough peer review

• Inclusion in PubMed and all major indexing services

• Maximum visibility for your research Submit your manuscript at

www.biomedcentral.com/submit

Submit your next manuscript to BioMed Central and we will help you at every step:

26. Fine JP, Gray RJ. A proportional hazards model for the subdistribution of a competing risk. J Am Stat Assoc. 1999;94:496–509.

27. Patente TA, Mohammedi K, Bellili-Munoz N, Driss F, Sanchez M, Fumeron F, et al. Allelic variations in the CYBA gene of NADPH oxidase and risk of kidney complications in patients with type 1 diabetes. Free Radic Biol Med. 2015 (in press).

28. Mohammedi K, Bellili-Munoz N, Marklund SL, Driss F, Le Nagard H, Pat- ente TA, et al. Plasma extracellular superoxide dismutase concentration, allelic variations in the SOD3 gene and risk of myocardial infarction and all-cause mortality in people with type 1 and type 2 diabetes. Cardiovasc Diabetol. 2015;14(1):163.

29. Sahakyan K, Klein BE, Lee KE, Myers CE, Klein R. The 25-year cumulative incidence of lower extremity amputations in people with type 1 diabetes.

Diabetes Care. 2011;34(3):649–51.

30. Adler AI, Erqou S, Lima TA, Robinson AH. Association between gly- cated haemoglobin and the risk of lower extremity amputation in patients with diabetes mellitus-review and meta-analysis. Diabetologia.

2010;53(5):840–9.

31. Ebskov LB. Relative mortality in lower limb amputees with diabetes mel- litus. Prosthet Orthot Int. 1996;20(3):147–52.

32. Cusick M, Meleth AD, Agron E, Fisher MR, Reed GF, Knatterud GL, et al.

Associations of mortality and diabetes complications in patients with type 1 and type 2 diabetes: early treatment diabetic retinopathy study report no. 27. Diabetes Care. 2005;28(3):617–25.

33. Lavery LA, Hunt NA, Ndip A, Lavery DC, Van Houtum W, Boulton AJ.

Impact of chronic kidney disease on survival after amputation in indi- viduals with diabetes. Diabetes Care. 2010;33(11):2365–9.

34. Samann A, Tajiyeva O, Muller N, Tschauner T, Hoyer H, Wolf G, et al. Preva- lence of the diabetic foot syndrome at the primary care level in Germany:

a cross-sectional study. Diabet Med. 2008;25(5):557–63.

35. Klein R, Knudtson MD, Lee KE, Gangnon R, Klein BE. The Wisconsin epidemiologic study of diabetic retinopathy: XXII the twenty-five-year progression of retinopathy in persons with type 1 diabetes. Ophthalmol- ogy. 2008;115(11):1859–68.

36. Miller RG, Secrest AM, Ellis D, Becker DJ, Orchard TJ. Changing impact of modifiable risk factors on the incidence of major outcomes of type 1 diabetes: the Pittsburgh epidemiology of diabetes complications study.

Diabetes Care. 2013;36(12):3999–4006.

37. Fromy B, Abraham P, Bouvet C, Bouhanick B, Fressinaud P, Saumet JL. Early decrease of skin blood flow in response to locally applied pressure in diabetic subjects. Diabetes. 2002;51(4):1214–7.

38. Khan F, Elhadd TA, Greene SA, Belch JJ. Impaired skin microvascular function in children, adolescents, and young adults with type 1 diabetes.

Diabetes Care. 2000;23(2):215–20.

39. Koitka A, Abraham P, Bouhanick B, Sigaudo-Roussel D, Demiot C, Saumet JL. Impaired pressure-induced vasodilation at the foot in young adults with type 1 diabetes. Diabetes. 2004;53(3):721–5.

40. Sabatier F, Darmon P, Hugel B, Combes V, Sanmarco M, Velut JG, et al.

Type 1 and type 2 diabetic patients display different patterns of cellular

microparticles. Diabetes. 2002;51(9):2840–5.